Concentrating Solar Power - ACS Publications - American Chemical

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Concentrating Solar Power Lee A. Weinstein,† James Loomis,†,‡ Bikram Bhatia,† David M. Bierman,† Evelyn N. Wang,† and Gang Chen*,† †

Department of Mechanical Engineering, Massachusetts Institute of Technology, Cambridge, Massachusetts 02139, United States Department of Mechanical Engineering, University of Auckland, Auckland 1010, New Zealand



6.2.1. Supercritical Steam 6.2.2. Supercritical CO2 6.2.3. Combined Cycles 6.3. Direct Heat-to-Electricity Conversion 6.3.1. Solar Thermoelectric Generator (STEG) 6.3.2. Solar Thermophotovoltaics (STPV) 7. Concluding Remarks Author Information Corresponding Author Notes Biographies Acknowledgments References

CONTENTS 1. Introduction 1.1. CSP Configurations 1.2. Maximum Efficiency of a CSP System 2. Concentrator/Reflector 2.1. Concentrator Characteristics 2.2. Optical Properties and Characterization 2.3. Reflector Materials 2.4. Reflector Degradation 3. Receiver/Absorber 3.1. Receiver Efficiency 3.2. Spectrally Selective Surfaces 3.2.1. Intrinsic Absorbers 3.2.2. Cermet Absorbers 3.2.3. Semiconductor Absorbers 3.2.4. Thin-Film Multi-layer Absorbers 3.2.5. Structured Surface Absorbers 3.2.6. Photonic Crystal Absorbers 3.3. Angularly Selective Surfaces 3.4. Receiver Technologies 3.4.1. Vacuum Tubes 3.4.2. LFR Receivers 3.4.3. Central Receivers 4. Heat-Transfer Fluid 4.1. Desired Characteristics and Figures of Merit 4.2. Types of Heat-Transfer Fluids 4.2.1. Oils 4.2.2. Molten Salts 4.2.3. Other Liquids 4.2.4. Pressurized Gases 4.2.5. Steam 5. Thermal Energy Storage 5.1. Sensible Storage 5.2. Latent Storage 5.3. Thermochemical Storage 6. Heat Engine 6.1. Heat Engine Efficiency 6.2. Novel Cycles

© XXXX American Chemical Society

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1. INTRODUCTION Solar energy is a bountiful renewable energy resource: the energy in the sunlight that reaches Earth in an hour exceeds the energy consumed by all of humanity in a year.1 While the phrase “solar energy conversion” probably brings photovoltaic (PV) cells to mind first, PV is not the only option for generating electricity from sunlight. Another promising technology for solar energy conversion is solar−thermal conversion, commonly referred to as concentrating solar power (CSP).2 The first utility-scale CSP plants were constructed in the 1980s, but in the two decades that followed, CSP saw little expansion.3,4 More recent years, however, have seen a CSP renaissance due to unprecedented growth in the adoption of CSP.3,5 Photographs of two operating CSP plants, a parabolic trough collector plant and a central receiver (or “power tower”), are shown in Figure 1. There are five steps to a conventional CSP system (illustrated in Figure 2): 1. concentration: sunlight incident on a large concentrator is redirected to a much smaller receiver 2. absorption: sunlight incident on the receiver is converted to heat by an absorber 3. transfer: heat is carried away from the absorber by a heattransfer fluid (HTF) 4. storage: heat can be stored in a thermal energy storage system for later use 5. generation: the HTF delivers heat to a heat engine, which generates electricity Special Issue: Solar Energy Conversion Received: July 7, 2015

A

DOI: 10.1021/acs.chemrev.5b00397 Chem. Rev. XXXX, XXX, XXX−XXX

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primary figure of merit for a CSP plant is the levelized cost of energy (LCOE, sometimes also called levelized cost of electricity or levelized energy cost), which represents the cost of electrical energy produced from the plant (typically given in units of cents per kilowatt hour) including capital costs and operations and maintenance costs.11,12 Thus, in addition to efficiency, affordability and reliability are very important to the feasibility of new CSP solutions. 1.1. CSP Configurations

There are a number of concentrator configurations that are commonly used in CSP systems. The first step of concentrating sunlight from a concentrator to a receiver is not necessary for all solar−thermal applications; however, for electricity generation it is almost always a requirement. CSP systems require concentration to be efficient, as otherwise system losses would be dominated by the large receiver areas at the high temperatures required to drive a heat engine efficiently. The level of concentration can be characterized by the concentration ratio, which is the ratio of the concentrator aperture area (the large mirror area intercepting sunlight) to the receiver aperture area (the small receiver area where the sunlight is redirected). Because concentration is required, CSP can only use the direct portion of sunlight (diffuse sunlight cannot be concentrated easily), which limits the best locations for CSP plants to areas with high average annual direct normal irradiation.13 Due to the solar progression across the sky (daily in the east−west direction and both daily and seasonally in the north−south direction), two-axis tracking is required to maintain a concentrator normal to the sun. With two-axis tracking, sunlight can be focused approximately to a point (“point-focus”). While the sun has both east−west and north− south movement, most of its daily movement is in the east− west direction. If one only tracks a concentrator in the east− west direction, sunlight can be focused approximately to a line (“line-focus”). Both line-focus and point-focus concentrators can be found in commercial use.14 Point-focus systems can achieve higher concentration ratios (∼1000×), but the required two-axis solar tracking is more complex and more expensive to implement. Line-focus systems have lower concentration ratios (∼80×) but use simpler, less expensive one-axis solar tracking. Another distinction between different types of concentrators is whether the collecting surface is continuous or made up of discrete facets. Concentrators with continuous surfaces can achieve higher concentration ratios, as there is no sunlight lost between facets, and tracking is simpler since only one surface needs to be actuated. When using a continuous surface, the focal axis should always intersect both the receiver and the sun, so the receiver is typically mounted with the reflector in one assembly, limiting the receiver size. Concentrators with discrete facets can cover a greater area since the receivers can be stationary (they do not need to be tracked with the reflecting surfaces). Additionally, wind loading is typically a smaller concern for discrete facets since they can be kept closer to the ground (the stationary receivers in this case are still elevated, so wind loading should be considered, but they are less susceptible to damage than reflector elements). The four combinations of these two distinctions (point-focus vs line-focus and continuous surface vs discrete facets) result in the four primary concentrators for CSP systems: parabolic trough collectors (PTCs), linear Fresnel reflectors (LFRs),15,16 parabolic dish reflectors, and heliostat fields, which are all shown in Figure 3. In a PTC, a long, curved, trough-shaped

Figure 1. Photographs of two concentrating solar power plants: (a) Solana Generating Station (proprietary technology of Abengoa Solar, S.A.), a parabolic trough collector plant in Phoenix, Arizona. Original photo by James Loomis. (b) Solar Two, a “power tower” plant near Barstow, California. Reprinted with permission from ref 6. Copyright 2015 Elsevier.

Figure 2. Illustrated components of a conventional CSP system: (1) concentrator, (2) receiver, (3) heat-transfer fluid, (4) thermal energy storage, and (5) heat engine.

It is worth noting that there are many uses for thermal energy, and solar−thermal systems are not limited to electricity generation;7 however, this Review will be limited in scope to address technologies that generate electricity. Transfer, the third step on this list, is not strictly necessary for CSP systems (e.g., the absorber can be directly coupled to the heat engine); however, all currently operating utility-scale CSP plants use HTFs. Storage, the fourth step on this list, is optional for CSP systems; however, it is one of the primary advantages compared to other renewable electricity technologies and, as such, is an important step to cover. Similar to most renewable energy technologies at the time of writing, CSP is not cost-competitive with conventional fossilfuel technologies without the aid of governmental subsidies or regulatory advantages.8 To reach cost parity with conventional energy sources (i.e., fossil fuels), advances that reduce CSP plant construction costs and improve CSP plant efficiency are needed.9 Given current cost estimates for CSP generated electricity, reaching parity would require about half the current plant cost or double the current efficiency (realistically a combination of both reduced cost and increased efficiency will be pursued).10 An important piece of the economics of CSP plants is system design (e.g., navigating the trade-off between the size of the plant power block and the size of the collector field);9 however, this Review will not focus on these issues. Rather, this Review will provide a brief overview of the main types of CSP plants, cover basic CSP operating principles, and focus on materials issues concerning the performance of CSP components. Since cost is the primary driver of utility-scale CSP technology, improvements purely in performance are not sufficient for commercial adoption. Rather than efficiency, the B

DOI: 10.1021/acs.chemrev.5b00397 Chem. Rev. XXXX, XXX, XXX−XXX

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mirrors track the sun across the sky to reflect sunlight to a central, raised receiver. Thus, PTCs and LFRs are line-focus systems, while parabolic dish reflectors and heliostat fields are point-focus, and PTCs and parabolic dishes use continuous surfaces, while LFRs and heliostat fields use discrete facets. It should be noted that parabolic dish systems sometimes have discrete reflector facets that form the overall parabolic shape, but since these facets are fixed in position relative to each other, they can be effectively considered a continuous reflective surface. While these characteristics in principle only determine the concentrator of the CSP system, in practice the concentrator type determines many of the operating conditions of the overall system. This connection between concentrator type and plant operating conditions is a result of the concentrator being paramount in determining the receiver concentration ratio and the overall plant size. As an example, parabolic dish plants are almost ubiquitously referred to as dish Stirling systems, due to how commonly they are paired with a Stirling engine to convert heat to electricity.17 Similarly, plants that use a heliostat field as the concentrator are often called power tower or central receiver systems, referring to the large tower where sunlight is focused at the center of the field. While in principle lenses can also be used as the concentrating element in a solar collector, there has been limited deployment in CSP, primarily due to higher cost per area than reflector systems and difficulties in making precise lenses at the large scales required for CSP. Significant progress has been made in optical designs of Fresnel lenses, and Fresnel lenses have seen use in commercial concentrated photovoltaic (CPV) systems.19 However, in order for Fresnel lenses to achieve substantial adoption in CSP, they would need to be made larger and cheaper. To give an idea of the basic characteristics of the different types of CSP plants, Table 1 lists typical LCOE, annual efficiency, peak efficiency, operating temperature, and concentration ratio of the four types of CSP systems. It should be noted that the values reported here are characteristic of the system type, but individual plants may have different values. Here, “peak efficiency” refers to the highest instantaneous solarto-electricity efficiency achieved (typically during solar noon), while “annual efficiency” (annual electrical energy output divided by annual solar energy incident on the solar collectors during operating hours) considers the effect of daily and seasonal variation on performance and is more relevant to LCOE than peak efficiency. It is difficult to assign characteristic LCOE values, as estimated LCOE values for the different CSP technologies vary widely by reference, even when considering only the LCOE of electricity generated by utility-scale plants currently in operation.13,14,20,21 This uncertainty is somewhat exacerbated by the limited number of plants operating for all the technologies besides PTCs. While the current cost of electricity from CSP is greater than the cost from conventional

Figure 3. Illustrations and photographs of CSP plant configurations. (a) Illustration of a parabolic trough collector and (b) photo of a PTC. Reprinted with permission from ref 18. Copyright 2012 Elsevier. (c) Illustration of a linear Fresnel reflector and (d) photo of the FRESDEMO LFR project demonstration at Plataforma Solar de Almeria in Spain. Reprinted with permission from ref 16. Copyright 2014 Elsevier. (e) Illustration of a parabolic dish and (f) photo of Maricopa Solar project in Arizona. Reprinted with permission from ref 6. Copyright 2015 Elsevier. (g) Illustration of a heliostat field (“power tower”) plant and (h) photo of Solar Tres in Sevilla, Spain. Reprinted with permission from ref 6. Copyright 2015 Elsevier.

mirror tracks the sun from east to west and concentrates sunlight on a pipe at the focus of the curved mirror, with the whole assembly rotating together. In an LFR, long mirrors tracking the sun from east to west reflect sunlight onto a fixed, raised receiver. The “Fresnel” in this concentrator’s name originates from the many reflector elements approximating a continuous curve, as in a Fresnel lens. With a parabolic dish, the sun is tracked on both axes across the sky, and sunlight is focused on a receiver that moves with the dish, such that it is always on-axis with the sun. In a heliostat field, individual

Table 1. Typical Performance Metrics for the Four Primary CSP Plant Configurations10,13,14,21,23−26

PTC heliostat/power tower LFR parabolic dish

LCOE (U.S. $/kWh)

annual efficiency (%)

peak efficiency (%)

operating temperature (°C)

concn ratio

0.16−0.40 0.13−0.30 0.14−0.45 no commercial plants

14 16 13 20

25 22 18 32

400 400−600 300−400 550−750

80 1000 30 1500

C

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Table 2. Large and Notable Operating CSP Plants34 name

gross capacity (MW)

location

concentrator type

Ivanpah

392

San Bernardino, CA, USA

SEGS Mojave Solar Project Solana Generating Station Genesis Solar Energy Project Solaben Solnova Andasol Extresol

354 280 280 250 200 150 150 150

Dhursar Martin Next Generation Solar Energy Center Puerto Errado

125 75

Mojave Desert, CA, USA Barstow, CA, USA Gila Bend, AZ, USA Blythe, CA, USA Logrosan, Spain Sanlucar la Mayor, Spain Guadix, Spain Torre de Miguel Sesmero, Spain Dhursar, India Indiantown, FL, USA

31.4

Murcia, Spain

start of operation

heliostat/power tower PTC PTC PTC PTC PTC PTC PTC PTC

1984 2014 2013 2014 2012 2010 2008 2010

LFR PTC

2014 2010

LFR

2009

notes

2014

6 h thermal storage

7.5 h thermal storage 7.5 h thermal storage

integrated solar combined cycle

are dropping, CSP with thermal storage is predicted to be cheaper than PV with battery storage.33 While CSP has not seen as widespread adoption as PV, it does account for a nontrivial amount of current global renewable electricity generation. By 2013, there was about 3.4 GW of installed CSP operational capacity worldwide, with the great majority in the USA and Spain.3 Most of the current installed capacity uses PTCs; however, the CSP technologies being installed are diversifying. As an example, the largest CSP plant in operation (both in terms of land area and peak power output) is the BrightSource Ivanpah plant, which uses a heliostat field collector. Some of the most notable plants currently operating are listed in Table 2. As it is the most mature technology, many of the largest companies in CSP work with PTCs (sometimes in addition to other technologies), such as Abengoa Solar, Acciona, Rioglass, Schott Solar, and Torresol Energy. There are also large companies that work with power tower plants (e.g., BrightSource and SolarReserve), as well as LFR technologies (e.g., Areva Solar and Novatec Solar), driven by the potential for lower LCOE. While there are no commercial-scale parabolic dish plants currently operating, a few companies are working with this technology, such as Ripasso Energy for dish Stirling systems and Heliofocus for hybridization with coal plants.

sources, many parties are optimistic about significant LCOE reduction in the next decade for CSP.13,21,22 PV currently has the largest deployment among solar electricity technologies, with the LCOE of electricity from PV quickly dropping over the past decade,3 but there are a few differences between CSP and PV that make CSP worth pursuing, even given the lower cost of PV. Many of the practical differences arise from the fact that CSP plants use wellestablished turbine technologies to generate electricity. Turbines have much different scaling than PV systems, and become more efficient and cost-effective with increasing size, so CSP can excel in large installations. On the other hand, this limits small plants, and there are effectively no options for residential-scale CSP installations (an area where PV shines). A large hurdle for constructing CSP plants is financing them, as capital costs are very high (typical plant construction costs are in excess of U.S. $1 billion) and payback periods are long for CSP projects.27 If a way could be found for CSP to operate efficiently and cost-effectively in small-scale plants, it would lower the capital costs required to undertake a CSP project and accelerate the learning cycles for CSP technologies. Another interesting opportunity for CSP that arises from its use of conventional turbine generators is that CSP can be retro-fitted onto existing fossil fuel plants to reduce their fuel consumption and replace that input with solar energy.28,29 A significant advantage that CSP has over PV, which arises from its intermediary use of heat, is the potential for thermal storage.30 With a PV system, electricity is produced only when the sun is shining on the PV cells. Production of electricity is interrupted when a cloud passes over the PV panels and when the sun sets. For a PV system, if electricity is desired when the sun is not shining, then collected electricity must be stored, but rechargeable battery technology is very expensive, which limits the potential to use PV with storage in practice. In contrast, CSP systems can store the thermal energy they collect inexpensively, which can be converted to electricity later, on demand. By using thermal storage, electricity can be produced from solar−thermal systems reliably even when the sun is no longer shining on the collector, which increases the value of CSP plants.31 A recent study by Jorgenson et al. found that electricity produced by CSP with storage could be more than twice as valuable to a utility provider as electricity produced from PV.32 Additionally, while the prices of PV and batteries

1.2. Maximum Efficiency of a CSP System

A question naturally arises when considering CSP: “What is the highest efficiency a CSP system can achieve?” While LCOE is more important in practice, efficiency is a strong lever of LCOE, and finding maximum efficiency is a tractable thermodynamics problem (whereas finding minimum LCOE is not). The maximum efficiency can be determined most easily by separating system efficiency into two sub-efficiencies: the sunlight-to-heat conversion process (receiver efficiency) and the heat-to-electricity conversion process. The receiver efficiency is calculated as the absorbed heat minus any losses, divided by the solar power incident on the receiver. A simplified version of receiver efficiency, ηrec (which will be discussed further in section 3), assuming the only loss is radiation from the absorbing surface (the only thermodynamically required loss), is given by ηrec = α − D

4 εσ(TH4 − Tamb ) ηconcCG

(1) DOI: 10.1021/acs.chemrev.5b00397 Chem. Rev. XXXX, XXX, XXX−XXX

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where α is receiver absorptance, ε is receiver emittance, σ is the Stefan−Boltzmann constant, TH is the receiver temperature, Tamb is the ambient temperature, ηconc is the concentrator efficiency (ratio of sunlight directed to the receiver by the concentrator divided by sunlight incident on the concentrator), C is the concentration ratio, and G is the solar insolation. The efficiency of the heat-to-electricity conversion process is well known to be limited at the Carnot efficiency. In the case where the heat engine converts at Carnot efficiency, the total efficiency is thus given by the product of the receiver efficiency and Carnot efficiency: 4 ⎛ ) ⎞⎛ T ⎞ εσ(TH4 − Tamb ⎟⎟⎜1 − amb ⎟ η = ⎜⎜α − TH ⎠ ηconcCG ⎝ ⎠⎝

2. CONCENTRATOR/REFLECTOR The concentrator of a CSP system uses reflector facets to optically concentrate solar energy and direct this concentrated flux to the receiver. The concentrator consists of a combination of reflector, structural or supporting elements, and a one-axis (for PTC and LFR) or two-axis (for dish and helisostat) tracking system.36 Concentrators are used in CSP systems because concentration is required for efficient conversion at high operating temperatures;37 however, there are additional benefits such as reducing the amount of costly receiver materials needed. While mirror materials are usually much less expensive than the materials used for the receiver on a per area basis, the concentrator typically accounts for the largest amount of capital investment among all subsystems in a CSP project.38 As such, concentrator systems present an attractive target for cost reduction.39 Furthermore, reflector cost makes up approximately half of the concentrator cost, so low-cost mirrors are an ongoing area of research.40 Reflectors with lower cost, improved optical performance, higher durability, and lower maintenance/cleaning requirements are highly desirable and represent key areas of research. This section begins with a discussion of the important characteristics of concentrators and reflectors, and then reviews the materials commonly used in reflectors, and finally discusses challenges with reflector degradation and methods for its prevention.

(2)

One ideal receiver would be a blackbody absorber with the maximum possible concentration ratio incident on it. While it may not be immediately clear why a maximum concentration ratio exists, from a thermodynamics standpoint this arises because arbitrarily high concentration ratios could lead to arbitrarily high temperatures.35 At some point this would lead to heat flowing from the sun to an absorber hotter than the sun, violating the second law of thermodynamics. From an optical standpoint, the limited concentration ratio arises from the finite solid angle of the sun in the sky on Earth, leading to a non-zero divergence angle of sunlight at the Earth’s surface. If, by contrast, there was an infinitesimal point source illuminating the Earth with perfectly collimated radiation, it would be possible to concentrate that light to an arbitrarily high ratio. The maximum value of ηconcCG is thus the flux at the surface of the sun (σT4sun), which assumes a concentrator efficiency of unity and the maximum concentration ratio. The efficiency of such an ideal system can therefore be given by ⎛ T 4 − T 4 ⎞⎛ T ⎞ η = ⎜1 − H 4 amb ⎟⎜1 − amb ⎟ TH ⎠ Tsun ⎠⎝ ⎝

2.1. Concentrator Characteristics

A concentrator can be characterized by its concentration ratio and concentrator efficiency. The geometric concentration ratio refers to the ratio of the concentrator aperture area (the large mirror area intercepting sunlight) to the receiver aperture area (the small receiver area where the sunlight is redirected). Stated more intuitively, it is the maximum possible ratio to which the concentrator is designed to concentrate sunlight, so a concentrator with a geometric concentration ratio of 10× aims to provide a radiative flux 10 times that of direct sunlight to the receiver. One-axis systems typically have concentration ratios less than 100×, while two-axis systems typically have concentration ratios greater than 500×. It should be noted that, by this definition, PTC concentration ratio is typically around 80−100×; however, if the receiver surface area (given by PTC tube receiver circumference) is used rather than receiver aperture area (given by tube diameter), then the concentration ratio will be smaller by a factor of π, and some literature follows this convention.41 The concentrator efficiency refers to the ratio of sunlight that reaches the receiver divided by the sunlight incident on the concentrator. Concentrator efficiency drops below unity in real systems due to imperfect reflector materials and challenges associated with varying solar elevation (e.g., cosine losses from angled reflectors when the sun is low in the sky). The optical properties of the reflectors and the design of the concentrator (e.g., placement of heliostats relative to the central receiver42,43) are both important to achieving high concentrator efficiency; however, this Review only focuses on reflector properties. Ideally, all concentrators would be able to achieve extremely high concentration ratios; however, in practice the concentration ratio is limited due to the finite divergence angle of sunlight on Earth (as previously mentioned in section 1.2). The maximum achievable concentration ratio, Cmax, is determined by the rim angle of the concentrator, ψrim, and given by conservation of etendue:35

(3)

It is typical to take Tamb to be 300 K (27 °C) and Tsun to be 5800 K (∼5500 °C, the apparent sun surface temperature). Using these values, efficiency is maximized when TH is set at 2480 K (∼2200 °C), which yields an efficiency of about 85%. Systems today fall short of this efficiency for a number of reasons. An obvious reason is that the Carnot limit cannot be reached for practical heat engines. Another reason is that current systems do not operate at ∼2200 °C, due to the limited stability of absorbers, HTFs, and heat engines. Finally, current solar receivers are not perfect. There are other ways to achieve a perfect receiver besides the maximum concentration that was explored in this exercise, but all current technologies fall short of ideal performance (other techniques for improving receiver efficiency will be discussed in section 3). This Review addresses research areas where performance can be brought closer to ideal, and some of the associated challenges. This Review will discuss different subcomponents of a CSP system in the order that energy transfers through the CSP system: concentrator/reflector (section 2), receiver/absorber (section 3), heat-transfer fluid (section 4), thermal storage (section 5) and heat engine (section 6). Each section will cover the properties required for high performance, the current state of the art used in the field, and current research directions to improve performance even further. E

DOI: 10.1021/acs.chemrev.5b00397 Chem. Rev. XXXX, XXX, XXX−XXX

Chemical Reviews Cmax,1‐ax =

Cmax,2‐ax

Review

sin ψrim sin θsun

⎛ sinψrim ⎞2 =⎜ ⎟ ⎝ sinθsun ⎠

concentrators are exposed to additional stresses beyond those experienced by the primary mirror, including higher radiation fluxes and elevated temperatures.37

(4)

2.2. Optical Properties and Characterization

Low-cost and robust reflector materials are required in order to maintain high specular reflectance properties during exposure to harsh outdoor oxidizing/corrosive environmental conditions (such as heat, humidity, wind loading, salt spray, etc.) over the 10−30 year system lifetimes.47 As summarized by Brogren et al., concentrating reflectors must fulfill a number of different, and oftentimes competing, roles.48 These roles include aspects such as providing high reflectance of incident solar radiation onto the receiver/absorber, maintaining high reflectance values over the system lifetime, low cost, low operation and maintenance (O&M) costs, and high mechanical strength (suitable to handle wind/snow loading, etc.). Furthermore, mirrors should be lightweight, utilize environmentally benign fabrication techniques and construction methods (or at least low impact compared to competing technologies), and to some extent be aesthetically pleasing (depending on proximity to high population density areas). The primary optical property of importance for a reflector in a CSP collector is specular reflectance. In specular reflection, the reflected ray leaves the surface at the same angle at which the incident ray struck the surface (with respect to the surface normal) and the incident, reflected, and surface normal directions are coplanar (see Figure 5). Stated more simply,

(5)

where Cmax,1‑ax and Cmax,2‑ax are the maximum concentration ratios for one-axis and two-axis systems, respectively, and θsun is the divergence half-angle of sunlight on Earth (approximately 4.8 mrad, or 0.275°).44 The rim angle refers to the largest angle at which reflected sunlight from the concentrator strikes the receiver (see Figure 4a). For a flat receiver, the largest possible

Figure 4. Diagram illustrating (a) concentrator rim angle ψrim and (b) secondary reflector concept. The rim angle is the largest angle at which reflected sunlight from the concentrator strikes the receiver. A secondary reflector concentrates flux from the primary reflector further before directing it to the receiver.

rim angle is π/2, which corresponds to sunlight incoming from the entire hemispherical solid angle to which the receiver is exposed. For such a receiver, the maximum attainable concentration ratios are approximately 210× for a one-axis system and 43 000× for a two-axis system. Real concentrators cannot achieve such high concentration ratios due to imperfect tracking and imperfections in reflector surfaces. Reflector geometry can take a number of forms in the solar− thermal system between line-focus and point-focus as well as continuous and faceted concentrators. For continuous surfaces, the reflectors need to be curved in order to concentrate sunlight, whereas faceted surfaces can use curved or flat reflectors. From the names of the continuous surfaces (“parabolic trough collector” and “parabolic dish”), it is clear that a parabolic geometry is common for concentrators. Parabolic geometries are used because a parabola will reflect collimated rays to a point;45 therefore, sunlight, which is close to collimated, can be focused to small area by a parabolic reflector. In practice, parabolic geometries are sometimes approximated by spherical surfaces, which can be easier to manufacture. Because sunlight is not perfectly collimated, better concentrator performance can be achieved by using principles of non-imaging optics. For example, the compound parabolic concentrator (CPC), which incorporates two different parabolic sections in the one-axis case, can reach maximum solar concentration in theory.35 Faceted surfaces can focus sunlight with flat reflectors because the overall geometry still approximates a curved surface; however, using curved surfaces will allow improved performance.38,46 In addition to the primary reflectors described above, some systems utilize a secondary optical concentrator to further concentrate the sunlight before it reaches the receiver (see Figure 4b). While the potential for improved performance is promising, secondary

Figure 5. Illustration of specular reflectance and how it is measured. In specular reflection, the incidence angle θinc and reflection angle θref of the reflected ray are equal with respect to the surface normal, and the incident ray, reflected ray, and surface normal are coplanar. In measurements, reflected radiation is considered specular if it falls within the optical error cone of the reflected ray, defined by the divergence half-angle ϕ.

specular reflection is the reflective behavior one would expect of a mirror. This is in contrast to diffuse reflection, in which the reflected rays are scattered in all directions. Specular reflection is the only useful component of reflection for CSP collectors, because it allows incident direct sunlight to be redirected and concentrated, whereas diffuse reflection will be almost entirely lost to the surroundings. Furthermore, the only component of light that can be concentrated is direct illumination; diffuse or scattered radiation (e.g., sunlight on a cloudy day when the sun is blocked) is not concentrated.49,50 Three parameters that define the specular reflectance of a solar mirror are the wavelength of radiation (λ), incidence angle (θinc), and optical error (ϕ).51 The optical error refers to the divergence from the angle of reflection that is acceptable to still be considered specular reflection (nominally a 4 mrad half-cone angle for two-axis systems and a 12.5 mrad half-cone angle for one-axis systems, see Figure 5).47 A smaller optical error allows higher concentration ratios to be reached, but also requires F

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Figure 6. Examples of reflector construction: (a) thick glass mirror, (b) thin glass mirror, (c) aluminum reflector, and (d) polymer substrate reflector. Adapted with permission from ref 47. Copyright 2005 American Society of Mechanical Engineers.

developed and followed the measurement standards) in hemispherical reflectance (ρh, ratio of sunlight reflected in any direction to incident sunlight) of up to 0.02 and specular reflectance (ρs) of up to 0.015 between the laboratories, indicating the importance of standardized testing procedures (for reference, the measured reflectance values were typically around 0.95 and the measurement uncertainty within a single laboratory was less than 0.005). Karim et al. pointed out that there is no mechanical durability standard related to the site exposure conditions, so they researched geologic and climate parameters to determine which ones most influenced surface wear rate of the solar mirrors.54 They then defined an approach to determine these parameters on potential deployment sites, helping to evaluate potential mirror damage that would be expected at a particular site. Due to the importance of concentrator performance in deployed systems, a number of methods have been developed to test the optical properties of reflectors installed in operating plants. These methods include commercially available reflectometers that can be used to point-check the specular reflectance of mirrors in the field, such as the 15R specular reflectometer from Devices and Services Instruments.55 Sutter et al. developed a spatially resolved reflectometer to monitor corrosion of solar reflectors that is able to measure properties over a relatively large area (5 cm diameter spot) at a resolution of 37 pixels/mm.51 Using a non-reflectometer approach, Valenzuela et al. presented a method to test optical performance of large-scale parabolic trough collectors that uses an energy balance on the HTF to measure concentrator efficiency, and demonstrated this method on a PTC prototype at the Plataforma Solar de Almeriá in Spain.56

more precise control of reflector surface roughness. For a given wavelength, incidence angle, and optical error, specular reflectance ρs,θ,λ is defined as the fractional proportion of an incident collimated beam reflected such that the angle of reflectance is equal to the angle of incidence, within the optical error.36 The solar weighted specular reflectance ρs can be calculated by integrating over the solar spectrum (with incidence angle typically taken as near normal to the mirror):52 ρs =

1 Gπϕ2



∫0 ∫Ω ρs,θ ,λ (θinc , λ)Gλ(λ) dΩ dλ s

(6)

where G is the solar insolation and Ωs is the solid angle of the reflected cone (reflected angle with error cone given by optical error ϕ). Specular reflectance can be affected by properties such as micro-roughness in the reflector surface, crazing of protective top coats, and impurities in protective glassall of which can reduce optical performance via reflectance of light outside of the target angle.47 Testing of optical properties and knowledge of reflector degradation over the system lifetime are essential to ensure adequate performance. Furthermore, thorough testing helps identify failure areas or weak points in material properties or fabrication techniques and enables targeting those specific areas for future research and development. NREL initiated an outdoor testing program in 1994, with the German Aerospace center (DLR) and Spanish research center (CIEMAT) joining in 1995 and 1996, respectively.40 DLR, CIEMAT, and NREL developed a clear definition of the method and requirements needed of commercial instruments for reliable reflectance results.53 For specular reflectance measurements, they recommend the use of a UV-vis-NIR spectrophotometer. A roundrobin test performed by the three laboratories showed surprisingly large differences (given that these laboratories G

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followed by an adhesive layer, and finally the substrate. Testing showed the durability of these mirrors to be equivalent to those of the higher lead counterparts.60 Accelerated testing indicated non-mirror back-protective paint applied after the mirrors were manufactured was not beneficial. While more environmentally friendly, the manufacturing process using the copper-free backing layer necessitates very strict quality control.60 Additional types of thick glass reflectors include Pilkington (UK, 4 mm) and Cristaleria Espanola S.A. (Spain, 3 mm), with reflectances of 93.3% and 92.8%, respectively. In trying to address formability issues associated with glass mirrors (that is, difficulty in manufacturing the mirrors to be the desired shape), Angel et al. reported on a new method using radiative heating to shape the solar concentrator mirrors.62 This high-volume manufacturing method can be applicable to both point and line concentration. They successfully demonstrated their radiative heating approach using thick glass mirrors (4 mm). Conversely, thin glass mirrors (Figure 6b) utilize 1000 °C) are not yet reachable due to receiver material limitations (as discussed in section 3), the operating temperatures achieved today (as high as 550 °C) result in a higher exergetic efficiency and lower LCOE. Additionally, molten salts can be directly used for thermal storage, which increases the hours of electricity production and further reduces the LCOE (discussed in section 5).210 Molten salts are typically binary and ternary compounds of inorganic ions and are divided in three main classesnitrates, chlorides and fluorides. From a thermophysical perspective, molten salts have much higher volumetric heat capacity, thermal conductivity, and comparable viscosity (at their respective operating temperature) compared to oil-based HTFs. Table 6 shows a representative list of a variety of molten salts and their thermophysical properties (adapted from Sohal et al.).211 A more complete list of physical properties of molten salts including density, viscosity, vapor pressure, surface tension and refractive index is provided by Janz.212 While salt-based HTFs are extremely promising, there is still room for significant improvement through further research and

development. One of the most important areas of research is the problem associated with the solidification of molten salts when the sun is not shining. For example, commercially available Hitec Solar Salt has a freezing point above 140 °C, which makes anti-freezing strategies a very important consideration due to the diurnal nature of solar radiation. Studies investigating the practicality of using molten salts in parabolic trough solar collectors also identified solidification of the salt as one of the largest issues facing this technology.213 The solidification of salt ultimately increases the cost through freeze prevention mechanisms. Conventionally, these issues are solved through continuous circulation of the fluid overnight (added pumping cost), auxiliary heaters to maintain a minimum temperature (added fuel cost), or electrical heaters along the pipeline (added electricity cost).210 It is then of great importance for researchers to investigate lowering the freezing point of these HTFs without compromising their thermalfluidic performance. The working principle of reduced melting points is related to the entropy of mixing of pure components.214,215 Recent work by Raade created a molten salt HTF with a novel mixture of inorganic salts.208 While many different unique mixtures exist, nitrate salts mixed with lithium, sodium, potassium, cesium, and calcium cations were investigated by the authors. This work demonstrated a low melting point around 65 °C by exploiting U

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Table 7. Thermophysical Properties of Some Ionic Liquids and Liquid Metals Used as Heat-Transfer Fluids204,206 fluid [emim][BF4] [bmim][BF4] [dmpi]Im

chemistry

temperature range

Ionic Liquids 1-methyl-3-ethylimidazolium tetrafluoroborate 14 to 446 °C 1-methyl-3-butylimidazolium tetrafluoroborate −87 to 424 °C 1,2-dimethyl-3-propylimidazolium bis(trifluorosulfonyl) 11 to 457 °C imide

density (kg/m3)

specific heat (kJ/kg·K)

1253 1175 1421

1.28 1.66 1.20

viscosity (mPa·s) 36 120 90

thermal conductivity (W/m·K) 0.20 0.19 0.13

Liquid Metals sodium lead−bismuth eutectic alloy molten tin

Na 44.5−55.5 wt% Pb−Bi

98 to 883 °C 125 to 1533 °C

808 9660

1.25 0.15

0.21 1.08

46.0 12.8

Sn

232 to 2687 °C

6330

0.24

1.01

33.8

organic cations result in strong ion−ion interactions that reduce the melting point drastically. Table 7 shows a list of ionic liquids with the imidazolium cation ([im]) investigated for solar−thermal applications and their thermophysical properties. Ionic liquids with other cations have also been studied, but the large and asymmetrical nature of [im] enables melting point depression below room temperature, which is quite attractive for CSP applications. Fredlake et al.205 report thermophysical properties of several [im]-based ionic liquids as well as how they change with chemistry. For instance, better thermal stability was associated with a large anion size, and the heat capacity was found to increase with increasing number of atoms in the ionic liquid. Overall, the density, heat capacity and thermal conductivity are comparable to synthetic oils; however, the viscosity is an order of magnitude higher. The low vapor pressure, stability over a large temperature range, as well as large heat capacity of ionic liquids suggests their suitability as HTFs for solar−thermal applications. However, issues such as higher pumping cost due to large viscosity and chemical compatibility with certain metals need to be addressed. Contamination by other species such as water, metal cations and chloride can alter the properties of the ionic liquids and deteriorate heat-transfer performance.204 The high cost and limited availability of ionic liquids are additional issues that need to be addressed. Other HTFs that have been widely studied in the past two decades consist of suspensions of sub-micrometer sized particles in a base fluid.218−220 The motivation behind nanofluids, as they are commonly known, is to enhance the heat-transfer performance by adding high-thermal-conductivity nanoparticles to the base fluid. However, the degree of performance improvement is not easy to predict in practice since it depends upon several competing factors such as the nanoparticle concentration, base fluid, and particle size and morphology.218 Nanofluids achieve higher thermal conductivities under proper conditions;221 however, that does not necessarily lead to a higher efficiency.219,220 In addition, high nanoparticle concentrations increase the viscosity (and pumping power) and may lead to sedimentation issues. Optimal nanoparticle size and cluster structure for nanofluids is also unclear. In contrast to thermophysical properties, which may not change drastically with the addition of nanoparticles, significant variation in the optical properties is possible. This allows the use of nanofluids for direct solar absorption in the collector.222,223 The solar absorption is enhanced by the addition of nanometer-sized

eutectic behavior. In addition, the thermal stability of the mixtures was demonstrated to about 500 °C. The chemical stability of molten salts was studied by Bradshaw and Siegel, and key degradation mechanisms were identified.216 The process of creating nitrite from nitrate species in the HTF occurs in the presence of oxygen and depends on its partial pressure in the surrounding environment. This work identified the nitrate−nitrate reaction as the characteristic process of degradation regardless of other existing components. In addition, nitrate salts react with carbon dioxide and moisture in the ambient air to form carbonates and oxides that degrade the salt mixture characteristics. Molten fluoride salts may release harmful acids such as HF with exposure to atmosphere and significantly increase metal corrosion rates. Therefore, it is important to carefully control the operating environment of some molten salts. Corrosion of metal alloys by molten salts is another issue that needs to be addressed. While several common nitrate-based salts, like Hitec, showed negligible corrosion of seamless stainless steel, other copper- and nickel-based alloys have reported corrosion rates of 1−10 μm per year at 570 °C. The corrosion rates can be >100 μm per year for halogen-based salts for high-temperature operation.199 Pipes and containers made from Inconel and Hastealloys were recommended for use with chloride and fluoride salts. More experimental studies are required to ascertain material compatibility of molten salts at different temperatures and in the presence of air and impurities. 4.2.3. Other Liquids. Several other liquids have been proposed as possible HTFs for solar−thermal applications. Most of these HTFs are currently in the research and development phase. These include ionic liquids and nanofluids that are actively being studied in the community. In addition, liquid metals have received significant attention as highperformance HTFs. The main thrust of research for liquid metals is to develop corrosion resistance and safe handling processes, while improving the heat-transfer performance is the main focus for ionic liquids and nanofluids. Ionic liquids are similar in nature to molten salts but, by definition, have freezing points below that of water.204 As discussed previously, molten salts are usually binary and tertiary compounds of inorganic ions (e.g., nitrates, chlorides, and fluorides). Significant suppression of the melting point, below room temperature, is achieved in ionic liquids by replacing the inorganic cations with large unsymmetrical organic cations, in addition to choosing eutectic compositions of binary and ternary systems as is done for molten salts.217 These large V

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Table 8. List of Pressurized Gas-Based Heat-Transfer Fluids237 fluid

temperature range

density (kg/m3)

specific heat (kJ/kg·K)

viscosity (mPa·s)

thermal conductivity (W/m·K)

air (30−100 bar) CO2 N2 water vapor (30−100 bar)

> −215 °C −73 to 1000 °C > −196 °C >234 °C

1.20 1.84 1.165 0.80

1.01 0.844 1.04 1.97

0.019 0.015 0.018 0.012

0.024 0.015 0.024 0.016

liquid metal HTFs using combinatorial material synthesis and thermochemical modeling.227 Another SunShot CSP project, led by Asegun Henry of Georgia Institute of Technology, is developing high-temperature (>1000 °C) thermochemical reactors using liquid metal HTFs to split water and generate hydrogen fuel.228 The main goals of the project are to lower the melting temperature and increase the upper limit of stable operation to above 800 °C. Other technical targets include parameters such as melting point (≤100 °C), thermal conductivity (>10 W/m·K), heat capacity (>2 MJ/m3·K), and viscosity (≤2 mPa·s) of the fluid.227 Additionally, the project has specific materials compatibility requirements as well as an aggressive cost goal of ≤$1/kgthe approximate price of popular molten salts. Other challenges include solidification, toxicity, corrosion, and reactivity with materials used for storage.228 Realizing these challenging targets would almost certainly lead to commercialization of liquid metal HTFs in solar−thermal systems. 4.2.4. Pressurized Gases. Pressurized gases offer several advantages over conventional HTFs in solar−thermal systems. Gases can reduce some of the complexities associated with the handling of HTFs such as chemical stability, material compatibility issues, sealing, and safety. In addition, they are capable of operating at higher receiver temperatures, which leads to higher energy conversion efficiency and lower operating cost. One of the promising prospects is direct expansion, i.e., using the same fluid in the receiver as well as in the turbine, eliminating the need for a heat exchanger and thereby reducing cost and complexity. However, one of the biggest drawbacks is the poor thermal capacity of gases, which may be overcome by using high pressures and large mass flow rates but makes the handling difficult and increases the cost. In this section we present some of the pros and cons of using pressurized gases such as CO2, N2, and air. Table 8 summarizes the temperature range and thermo-physical properties of these pressurized gas-based HTFs. CO2 has been widely studied as an HTF since its critical point (31 °C) is close to atmospheric temperature. Operation close to the critical point results in a significant enhancement of the cycle efficiency as a sharp increase is observed in the fluid heat capacity.229 Several studies have looked at enhancing the performance of linear (parabolic trough and Fresnel) solar− thermal systems by using close-to-critical CO2 cycles, multistage expansion/compression and regeneration, and optimizing the receiver design.201,229,230 However, one of the drawbacks of using CO2 is that the cycle must be closed; i.e., the fluid must be recirculated from the collector to the turbine, to the condenser, and back to the collector. This requires thicker pipes and measures to prevent leaks. Nonetheless, the promise of high efficiency and compact size achieved by combining directly with supercritical CO2 (s-CO2) cycles has made CO2 an appealing HTF.231−233 More details of the s-CO2 heat engines are provided in section 6.2.2. The use of air as an HTF, unlike CO2, is simpler since operating pressure can be close to ambient and perfect sealing

particles, comparable in size to the wavelength of incident radiation, to the base fluid. The extent of absorption is dependent on the particle size, particle shape, and the optical properties of the particle and base fluid.224 In general, greater absorption is achieved for fluids with non-metallic particles whereas metallic particles are desirable for a higher thermal conductivity. However, despite these advances, no study has shown evidence of nanofluid-based collectors outperforming commercial vacuum tube receivers.219 Several challenges need to be addressed for nanoparticle suspensions to be seriously considered for solar−thermal applications. Agglomeration in nanofluids due to particle− particle interaction can lead to significant changes in the effective thermal conductivity as well as viscosity. This can lead to fluctuations in the convective heat transport as well as pumping. More studies are necessary to understand the effect of agglomeration and instabilities on the thermophysical properties and heat-transfer performance. Additionally, the high viscosity of the nanofluids results in large pressure drop and high pumping power demand. The long-term stability of nanofluids also needs to be investigated since nanoparticles may lead to erosion of metal surfaces. In addition, the cost of production remains prohibitively high. Liquid metals, with their superior heat transport properties and high operating temperature, are a promising candidate for HTFs in CSP systems. Liquid metals have low vapor pressure, high thermal conductivity, and relatively low viscosity. As a consequence, FOMs of liquid metals are roughly 1 order of magnitude higher than molten salts and several orders of magnitude higher than pressurized air, allowing operation at higher heat flux densities. In addition, efficiency is improved by operating at fluid outlet temperatures in the 700−1000 °C range, compared with 400 °C) has a higher heat capacity than other gases, which increases the efficiency of the receiver as well as the power cycle. The feasibility of DSG was initially proven under real conditions at the Direct Solar Steam (DISS) facility at Plataforma Solar de Almeria in 1997−1998.238 The success of DISS and other studies led to the development of pre-commercial DSG facilities including a 5-MW INDITEP plant, and commercial power plants including 11-MW PS10 and 20-MW PS20 power plants in Andalusia, Spain.239,240 The results from these projects point toward a 8−14% reduction in LCOE compared to SEGSlike plants using synthetic oils as the HTF.241 Despite the promise of direct steam generation, several engineering challenges arising due to the two-phase flow need be addressed. These include the higher operating cost due to high pressure required to pump the two-phase mixture.207 The non-uniform heat transfer from pipe walls results in large temperature gradients, which can damage the pipes. At a system level, the stability of the temperature and pressure at the outlet is another big concern. Hence current research efforts are focused on the optimization of collector loop and power cycle design, the regulation of outlet temperature and pressure, and the reduction of collector piping costs.197

5. THERMAL ENERGY STORAGE To generate electricity on demand despite solar transients (such as clouds passing overhead or the sun setting), storage should be used. Storage is very valuable for renewable energy technologies, as storage makes them more reliable and more amendable to integration in the grid, and in the case of solar power allows electricity production to be shifted to meet peak demand.242,243 The most appropriate storage mechanism for use with CSP is thermal energy storage (TES) due to the intermediate heat step already present in CSP systems.244,245 Plants with solar multiples greater than unity, defined as the ratio of insolation to the receiver at the design point to the nominal heat input of the heat engine, can use the extra solar energy collected during peak sunlight hours to charge a TES system, and discharge the TES later to produce electricity when the sun is no longer shining. Thermal energy storage is one of the main advantages of CSP, because TES is significantly cheaper than other energy storage technologies (e.g., batteries) and is not compatible with other intermittent renewable energy technologies such as PV

⎛ T ⎞ B = Q ⎜1 − C ⎟ TH ⎠ ⎝

(19)

where TH is the temperature at which the heat is delivered and TC is the cold reservoir temperature. The exergetic efficiency ηB of the TES system can be calculated by

( ) (1 − )

Q out 1 − ηB =

Q in

TC TH,out

TC TH,in

(20)

where Qout and Qin refer to the heat recovered from and supplied to the TES system, respectively, and TH,out and TH,in refer to the temperature at which heat is recovered from and X

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There are three classes of TES materials: sensible, latent, and thermochemical. In sensible TES, heat is stored by raising the temperature of the storage material. In latent TES, heat is stored by subjecting the storage material to a phase change, thus latent TES materials are also referred to as phase change materials (PCM). In thermochemical TES, heat is stored by subjecting the storage material to a reversible chemical reaction, i.e., an endothermic reaction is facilitated by input heat, and heat can be recovered later by the reverse exothermic reaction. Sensible TES is the most commercially developed type of TES but has the lowest storage density, while thermochemical TES is the least developed but offers the highest potential for storage density (see Figure 18).244 As TES technologies mature, more

supplied to the TES system, respectively. Exergetic efficiency will be reduced below unity due to a few factors. The first factor is heat loss from the storage medium while it is being stored in its charged state (e.g., due to storing thermal energy materials at high temperature), which can be minimized with insulation and good container design. The second factor is the temperature drop required to charge or discharge the TES, and is influenced by the material thermal conductivity as well as system design. For example, to heat a storage medium to 400 °C, the charging process might need to be driven with an HTF at 410 °C, and in discharging that storage medium the HTF might be recovered at 390 °C. It can be challenging to minimize this exergy loss because the thermal conductivity of many TES materials is inherently low and because high-performance heat exchangers for efficiently charging and discharging the TES can lead to large system costs. It is important to consider exergetic efficiency, not just energy efficiency, in TES system design.250 Material properties and system design are both important to the TES system performance.245 This review will focus primarily on the choice of storage materials; however, some system design concepts will be covered briefly. One distinction in system designs is one-tank vs two-tank systems. In a onetank design, all the storage media is kept in the same container, but separated spatially (e.g., hot fluid at the top of the tank and cold fluid at the bottom in a thermocline design).251,252 In a two-tank design, the charged (e.g., hot) and discharged (e.g., cold) storage media are kept in separate tanks. One-tank systems have the potential to be cheaper, while two-tank systems allow decoupling of capacity from power.244,253−255 Another distinction in system types is direct versus indirect systems. In direct systems the HTF is also used as the storage medium while in indirect systems, the HTF transfers heat to another medium for storage. While indirect systems suffer from lower exergetic efficiency than direct methods, they are often used due to cost and storage density reasons.256 Another big part of system design is overcoming the low thermal conductivity of many TES materials. This is typically accomplished by using extended heat-transfer surfaces of materials with high thermal conductivity (e.g., metals) or heat pipes within the space where the TES is stored to quickly deliver or recover heat.257,258 Selecting an appropriate storage material is critical to a highperformance TES system. For all types of TES, there are certain desirable material characteristics:244 1. large gravimetric and volumetric storage capacity (high heat capacity/latent heat/heat of reaction as well as high density), to achieve high storage capacity 2. high thermal conductivity/diffusivity/effusivity, to achieve high thermal power and exergetic efficiency 3. high cycling and thermal stability, for long system lifetime 4. non-toxic, non-flammable, non-corrosive, and can be handled/contained easily, for ease of system implementation 5. small coefficient of thermal expansion, to minimize thermal stresses in system 6. inexpensive and Earth-abundant materials, for low system cost The first two characteristics relate directly to the system performance for achieving high storage capacity, high power, and high exergetic efficiency. The rest do not relate directly to these performance metrics but are critical to the implementation of actual systems and their feasibility as utility-scale, commercial solutions.

Figure 18. Different classes of thermal energy storage: sensible, latent (or phase change material), and thermochecmical. Sensible TES is the most commercially mature but has the lowest energy density, while thermochemical TES is the least commercially mature but has the potential for the highest energy density.

CSP plants will be able to move from sensible storage to latent and then thermochemical storage to take advantage of the higher storage densities. The rest of this section will cover these three classes of TESs, primarily addressing materials that have been investigated for use in TES systems. 5.1. Sensible Storage

Sensible TESs can be broadly divided into two categories: solid and liquid (gas is not used due to its low density). In principle, there are also systems that combine solid and liquid, for example, a fluid flowing over a packed bed of solid particles.244 This distinction is not overly important, as both solid and liquid sensible TESs operate on the same principle: heat is stored by heating up a material. In both cases, the heat stored Qsensible depends on the temperature change ΔT and the specific heat cp of the material: Q sensible = Vρc p(T2 − T1) = mc pΔT

(21)

where V is the volume of the storage material used, ρ is the density of the material, m is the mass of storage material used, and T2 and T1 are the charged and discharged material temperatures, respectively. Specific heat values of solids can be estimated by the Dulong−Petit law: qmol ≅ 3R ΔT

(22)

3R M

(23)

cp ≅

where qmol is the heat stored per mole, R is the universal gas constant, and M is the molar mass of the material. It was found that a mole of a material almost always has the same heat stored for an identical ΔT, which is approximately 25 J/(K·mol). This Y

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can equivalently be understood as a heat capacity of 3kBT for each atom from the equipartition theorem (six degrees of freedom, two vibration modes in each direction, multiplied by 1 /2 kBT for each degree of freedom), where kB is the Boltzmann constant and T is the absolute temperature of the material. Since interatomic spacing does not vary significantly among solids, the relative volume of atoms in the lattice (i.e., the packing fraction) does not change much between materials, which leads to similar volumetric energy densities ρcp. Because most non-porous materials have similar ρcp values (i.e., less than an order of magnitude variation among them), as shown in Figure 19, the energy storage in sensible TES technologies is

strongly driven by the volume of the system. The total capacity of the system (i.e., in kWht/m3 rather than kWht/m3·K) can be calculated by integrating the volumetric heat capacity over the operating temperature range. Larger operating temperature ranges will give higher capacities, but the system must be compatible with receiving heat over widely varying temperatures. Table 9 lists some materials that have been considered for sensible TESs, as well as their relevant properties. Sensible storage technologies are relatively mature, and deployed sensible TES systems have achieved efficiencies higher than 90%.259 The remainder of this section will discuss sensible TES materials in more detail. One well-established method for storing thermal energy uses a steam accumulator, which uses water as the TES material.265,266 In a steam accumulator pressurized, saturated water stores the thermal energy. To extract the thermal energy, steam is produced by lowering the pressure of the saturated water. While there is a phase change process occurring, thermal energy is stored in raising the temperature of the water, not in boiling it and converting it to steam. Since the thermal energy is extracted from the steam accumulator via the evaporated steam, the discharge rate is not limited by the thermal conductivity of water. Such a system can be charged with saturated water directly or can be fed with cool water and heated with a different HTF through a heat exchanger. Operating temperature and pressure in these systems are limited by the critical point of saturated water (374 °C, 221 bar). For its operational temperature range, a steam accumulator is a very cheap and energy dense option for TES. A deployed example of a steam accumulator used with CSP is at the Planta Solar towers in Sevilla, Spain, where such a system provides approximately 1 h of thermal storage, operating at temperatures from 250−300 °C.34,267

Figure 19. Volumetric heat capacity vs temperature for various materials. Discontinuities in curves correspond to phase changes. Adapted with permission from ref 244. Copyright 2012 Begell House, Inc.

Table 9. Selected Materials That Have Been Considered for Sensible TESsa material

a

operating temperature range (°C)

thermal conductivity (W/m·K)

density (kg/m3)

specific heat capacity (kJ/kg·K)

volumetric heat capacity (kWhth/m3·K)

water mineral oil synthetic oil silicone oil liquid sodium nitrite salts nitrate salts carbonate salts Hitec261 HitecXL262

200−300 200−300 250−350 300−400 270−530 250−450 265−565 450−850 220−600 120−500

Liquids 0.7 0.12 0.11 0.10 71 0.57 0.52 2 0.46 0.52

800 770 900 900 850 1825 1870 2100 1900 1990

4.9 2.6 2.3 2.1 1.3 1.5 1.6 1.8 1.5 1.4

1.09 0.56 0.57 0.52 0.31 0.76 0.83 1.05 0.79 0.77

cast iron cast steel sand/rocks/gravel concrete castable ceramic263 advanced concrete263 NaCl silica fire brick magnesia fire brick graphite264

200−400 200−700 200−300 200−400 200−390 200−390 200−500 200−700 200−1200 200−2000

Solids 37 40 1 1.5 1.35 1.0 7 1.5 5 40

7200 7800 1700 2200 3500 2750 2160 1820 3000 1900

0.56 0.60 1.30 0.85 0.87 0.92 0.85 1.00 1.15 1.75

1.12 1.30 0.61 0.52 0.84 0.70 0.51 0.51 0.96 0.92

Material properties are representative values from within operating temperature range. Values are from ref 260 unless noted otherwise. Z

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concretes with better thermal properties, and that are compatible with finned HTF heat exchanger designs.271 Concretes and castable ceramics have been developed with volumetric heat capacities greater than 0.7 kWhth/m3·K.263 For higher temperature applications, silica, alumina and magnesia bricks have been suggested with molten salt as the HTF.272 Another proposed TES material using sensible heat is graphite, due to its good high-temperature stability and high specific heat at elevated temperatures. The company Graphite Energy has a demonstration project integrating graphite TES into a 3-MW demonstration power tower plant in Lake Cargelligo, Australia.277

Oils are another liquid that have been considered for use as sensible TES materials. Mineral oil could be used as an effective thermal storage material with low cost; however, its flammability leads to safety concerns.259 Mineral oil also has a limited operating temperature range without going to expensive pressure vessels. While in principle synthetic oils or silicone oils could be used as a thermal storage material, they are too expensive to achieve a reasonable storage capacity at acceptable system costs. For higher temperature storage than can be achieved with a steam accumulator, molten salts are the best option. Salts have reasonably high storage densities and are inexpensive, making them an economical storage material.253 For molten salts, the operating temperature range is limited on the low end by the freezing temperature and on the high end by corrosion. Freezing is a major concern for these systems, as frozen salts can damage piping and pumps, so they are often equipped with protection measures such as auxiliary heaters.253 Nitrite, nitrate and carbonate salts all have reasonable properties as TES materials; however, improved properties (in terms of both cost and performance, especially lowering melting temperature) can be achieved by mixing salts. One commercially used salt mixture is NaNO3−NaNO2−KNO3 (0.07−0.40−0.53 by mass), which is known as Hitec.261 A slightly different mixture of Ca(NO3)2−NaNO3−KNO3 (0.48−0.07−0.45), known as HitecXL, has a lower melting point. Research effort continues to attempt to develop better molten salts for TES. Peng et al. designed a quaternary mixed molten salt for TES composed of K, NaNO2, Cl, and NO3 with a melting point as low as 172 °C for certain eutectic mixtures.268 Zhao and Wu demonstrated a mixed salt of KNO3, LiNO3, and Ca(NO3)2 with a very low melting temperature of 80 °C. Ionic liquids (salts with organic cations and low melting temperatures discussed previously in section 4) have also been considered for use as TES materials.269,270 Their low melting temperatures make freezing less of a concern than for molten salts. While their other properties (volumetric storage capacity and thermal conductivity) are similar to those of molten salts, ionic liquids are more expensive than molten salts, which has limited their adoption in commercial TES systems. Solids also offer promising, inexpensive sensible TES solutions.271,272 With a solid material as the TES, it is common to use a packed bed of solids with HTF running through to charge and discharge the system. If the HTF is a gas (e.g., air) its sole purpose is to transfer heat; however, if the HTF is a fluid, the fluid heat capacity will commonly be comparable to the solid and it thus can act as a supplementary storage material. At first glance, metals seem like they could provide a competitive TES material. Metals offer high thermal conductivity and heat capacity, which would lead to high system capacity and power, but they are significantly more expensive than other options.273 Due to their high cost, metals are used for enhancing the thermal conductivity of a TES system (e.g., through the integration of metal fins), but are not typically considered for use as the bulk storage material in TES systems. A very inexpensive approach is to use sand, gravel or concrete as the solid sensible TES material. With sand or gravel, a packed bed configuration is typically used; however, flowing sand configurations have also been proposed.274,275 Concrete can be formed into bricks and arranged in a packed bed configuration or HTF pipes can be set to run through large concrete blocks.260,276 Work has been performed to develop

5.2. Latent Storage

In latent TES, thermal energy is stored by subjecting the storage material to a phase change process, thus latent TES systems are commonly referred to as phase change materials (PCM). Typically the phase change process used is melting a solid into a liquid, but occasionally solid−solid phase changes are used (e.g., between two different crystalline phases). Liquid−gas phase changes are not used due to the large expansion undergone in boiling, which leads to either high storage volumes or strict pressure vessel requirements. In latent TES, the energy stored Qlatent depends on the latent heat (or enthalpy) of melting for the material Δhm: Q latent = VρΔhm = mΔhm

(24)

where V is the volume of the storage material used, ρ is the density of the material, and m is the mass of storage material used. Latent heat of melting roughly scales linearly with melting temperature for different classes of materials; e.g., metals tend to have a molar latent heat value of 1−1.5 times the melting temperature times the universal gas constant (8.3 J/mol·K).278 Thus, higher energy densities can typically be achieved for PCMs with higher melting temperatures, as shown in Figure 20; however, the intended application will limit the usable

Figure 20. Typical ranges of melting temperatures and volumetric latent heats for different categories of materials considered for PCM TES. There are metals and metal alloys with melting temperatures higher than 800 °C; however, there are limited examples with competitive latent heats at the time of writing.

melting temperature range. PCM storage can also take advantage of sensible temperature change if the operating temperature range extends significantly beyond the melting temperature. Latent TES offers a few advantages compared to sensible TES. First, the energy density is typically much higher, since Δhm ≫ cpΔT for most systems. Second, the charging and discharging processes usually occur at a constant temperature, AA

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Table 10. Selected PCM TES Materialsa material

phase change temperature (°C)

thermal conductivity (W/m·K)

density (kg/m3)

specific latent heat (kJ/kg)

volumetric latent heat (kWhth/m3)

ref

6760 2380

112 397

210 262

244 244

Zn Al

419 660

Metals 50 91

Mg−Zn (46−54) Mg−Cu−Zn (60−25−15) Al−Si (88−12) Al−Si (12−88) Zn−Cu−Mg (49−45−6)

340 452 557 576 703

Alloys n.a. n.a. n.a. 160 n.a.

4600 2800 2540 2700 8670

185 254 498 471 176

236 198 351 353 424

257 257 257 257 257

LiNO3 NaNO2 NaNO3 NaOH KNO3 KOH MgCl2 NaCl

254 270 306 322 337 380 714 800

Salts 0.6 0.6 0.51 0.8 0.45 0.5 n.a. 7

1780 1810 1910 2130 1880 2044 2140 2160

360 180 175 210 100 150 452 480

178 91 93 124 52 85 269 288

244 244 244 244 244 258 258 257

KNO3−KCl (95.5−4.5) NaCl−Li2CO3−Na2CO3 (24.5−20.5−55) K2CO3−Li2CO3−Na2CO3 (35−32−33) MgCl2−NaCl (52−48) K2CO3−Li2CO3 (65−35) BaCl2−KCl−CaCl2 (47−24−29) LiNaCO3−C (90−10)

320 393 397 450 505 551 510

2100 1800 1900 2230 2000 2930 2500

74 240 275 430 345 219 530

43 120 145 266 192 178 368

257 244 244 257 244 257 281

Salt Mixtures/Composites 0.5 1.0 n.a. 0.95 n.a. 0.95 4.3

a

Not all thermal conductivity values are available. In general, salts tend to have low values (50 W/m·K).

thermal conductivity of salts. PCM systems can be augmented with fins of higher thermal conductivity (e.g., metal) to increase the effective thermal conductivity of the material.257 Another system design encapsulates PCMs and stores the capsules in packed beds to enable faster charging and discharging, since the relevant length scale for heat penetration becomes the capsule diameter rather than the tank diameter.283 Graphite has also been used as a matrix to increase the effective thermal conductivity of PCMs.284,285 Similarly, an enhancement of thermal conductivity has been demonstrated by integrating carbon structures (e.g., graphite or carbon nanotubes) into the PCM at a microscopic level, with Ge et al. achieving a thermal conductivity of >5 W/m·K in LiNaCO 3 -based PCM composites.281 In order for PCM TES to become more widely adopted, it is important to find inexpensive PCM candidates with improved properties compared to what has already been proposed and demonstrated. In addition to new latent storage materials, it is also critical to find affordable materials to make containers, heat exchangers, and capsules that are compatible with the PCMs and allow for fast and efficient charging and discharging. Highperforming PCMs, appropriate materials to contain the PCMs, and good system design are all necessary for latent storage to be utilized in real applications.

which can be advantageous from a system standpoint for targeting a specific heat engine operating temperature. For noneutectic alloys there is a melting range rather than a specific melting temperature. For latent TES materials, a high enthalpy of melting is desired to achieve good energy density. Many different materials systems have been investigated in search of high latent heats.279,280 High thermal conductivity is also desirable to allow quick (and efficient) charging and discharging of the PCM. Some materials used or proposed for use in latent TES systems are listed in Table 10. Metals and metal alloys have been proposed as PCM TES materials, as they have properties that are desirable for PCMs: they have high thermal conductivity and large latent heat. While from a performance point of view metals are a promising option for PCM TES, they are expensive. The cost drawback can be addressed in part by alloying metals with cheaper materials. For example, aluminum silicon alloys have been shown to have good thermal properties, and silicon is inexpensive and Earth-abundant.282 Salts offer a more economical option than metals for a PCM TES. There is a wide range of melting temperatures for different single and mixed salts.280 While some salts have sufficient latent heat, they typically have very low thermal conductivity (450 °C, typically around 900 °C),287 which are not common in CSP plants now but may be appropriate for future, higher-efficiency, higher-temperature plants. As one example, calcium carbonate (CaCO3) can be reacted to form calcium oxide (CaO) and carbon dioxide at around 900 °C. A number of studies have been performed exploring this reaction for use as TES.295,296 The poor reactivity of the reactant leads to conversion efficiencies around 20% when the bulk of the calcium carbonate has been decarboxylated, which would need to be improved considerably for use in CSP applications. In redox reactions of metal oxides, energy is stored by reducing a metal oxide to form oxygen. An example metal oxide is cobalt(II,III) oxide (Co3O4), which can be reacted to form cobalt(II) oxide (CoO) and oxygen. Redox reactions of metal oxides for TES are relatively unstudied, but theoretically offer high energy density for high-temperature systems.287 While these thermochemical storage materials show great potential with high energy densities and an absence of thermal losses (which allows for the prospect of TES with unlimited storage time), much work remains to be done before thermochemical TES technology can be commercially adopted. From the chemical perspective, high reversibility of reactions must be demonstrated, along with reasonable reaction rates and conversion efficiencies. Affordable system designs are also necessary for commercial feasibility. If these obstacles can be overcome, it would improve the current suite of options for CSP storage, and allow CSP to play a more significant role in the global renewable energy portfolio.

input, and energy is stored in chemical bonds of the chemical product.286 The product of this reaction can be stored until the thermal energy needs to be recovered. To recover the thermal energy, the reverse exothermic reaction is performed, releasing the thermal energy for use with the heat engine to produce electricity. Such a chemical reaction can be written: ΔHr

AB XoooY A + B

(25)

where AB is the reactant (the discharged state), A and B are the products (the charged state), and ΔHr is the molar heat of reaction. Thermochemical energy stored is given by Q thermochemical = nA ΔHr

(26)

where nA is the number of moles of one of the products. Advantages of thermochemical storage include higher energy density than sensible or PCM storage, and no thermal losses, as typically the chemicals can be stored at room temperature in their charged state.287 Some chemical systems can also supply heat at different temperatures than that at which the heat is absorbed (called heat transformers when heat is supplied at a higher temperature and chemical heat pumps when heat is supplied at a lower temperature).244 Some chemical processes can be driven by sunlight directly rather than heat (these are known as “solar fuels”);288 however, such reactions will not be covered in this Review. One distinction between different types of thermochemical TES systems is open versus closed systems.244 In an open system, the reaction is performed at ambient pressure and exchanges gas with the atmosphere, whereas in a closed system the reaction occurs in a sealed container. Open systems are less expensive to implement; however, open processes are less controlled and can be contaminated by particulates from the environment. Another important distinction is the phases of the chemicals involved in the reaction. Some well-studied reactions involve only liquids and gases. For example, NaOH−water systems have been demonstrated; however, the operating temperatures are not high enough for CSP applications.289 Another reaction that has been demonstrated with parabolic dishes is disassociation of ammonia into nitrogen and hydrogen gases.290 A similar NH3SO4 system with higher storage density has been proposed but has yet to be demonstrated.287 Cyclohexane (C6H12) dehydrogenation (reacting to form benzene and hydrogen) is another potential reaction that has been proposed for use as thermochemical TES with reasonable energy density. Work has explored other organic systems as well, such as methane reforming; however, they have significantly lower energy densities. Challenges with these organic systems include the need for good catalysts and poor reaction reversibility.287 Much more effort has been focused on solid−gas reactions, such as dehydration of metal hydroxides or metal hydrides, decarboxylation (removing carbon dioxide) of metal carbonates, and redox reactions of metal oxides. An AC

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performance in system level analysis.9 A common (and reasonably accurate) way to estimate Chambadal−Novikov efficiency in the temperature range typical of CSP systems is to simply take two-thirds of the Carnot efficiency. The Carnot and Chambadal−Novikov efficiencies are shown in Figure 21 for

6. HEAT ENGINE The heat engine is the system in a CSP plant that converts the collected heat to electricity. This is traditionally achieved via a thermodynamic cycle converting the heat to mechanical energy, which is used to drive a generator and produce electricity (some alternatives exist at the research stage and will be discussed in section 6.3). The thermodynamic cycle typically has four steps: 1. a working fluid is compressed to high pressure 2. the fluid is heated using the solar energy input 3. the fluid is expanded to low pressure through a turbine (which produces mechanical work) 4. the fluid is cooled back to its initial temperature The net power output of the heat engine is given by the power produced by the expansion step minus the power input required for the compression step. Current CSP plants typically use Rankine cycles with water/steam as the working fluid, with water being evaporated during the heating portion of the cycle.21 The other commonly used cycle is a Brayton cycle, which uses a single-phase working fluid. Heat engines used in CSP plants share many parts with traditional (e.g., fossil fuel fired) power plants. Due to the long history of research into engines for use with fossil fuels, a great portion of the potential cost reduction in steam−Rankine and air−Brayton heat engines for use with CSP simply comes from scaling up the plant rather than technology improvements (scaling up these plants also leads to higher heat engine efficiency).297 However, there are some newer engines and working fluids being developed that could lead to cost reduction in CSP plants.298

Figure 21. Carnot and Chambadal−Novikov efficiencies for typical CSP operating temperatures as well as approximate efficiencies of real cycles.

operating temperatures typical of current systems (350−600 °C) up to temperatures that could be achieved with high concentration ratio concentrators and advanced receivers. Table 12 lists typical operating temperatures and efficiencies for heat engines that are or could be used with CSP.

6.1. Heat Engine Efficiency

6.2. Novel Cycles

While the heat engine should be reliable and ideally require low capital investment, the main performance metric of the heat engine is how efficiently it coverts heat to electricity. Increase in efficiency is mostly driven by operating at higher temperatures. The highest achievable efficiency is the well-known Carnot efficiency ηC, given by ηC = 1 − TC/TH, where TC is the temperature of the sink to which the heat is being rejected in the cooling step (i.e., cold side temperature) and TH is the temperature at which the heat is being supplied in the heating step (i.e., plant operating temperature). It is clear that increasing the operating temperature will increase the maximum achievable efficiency if the cold-side temperature can be held constant. Cold-side temperature should be kept as low as possible, which is limited in practice by the ambient temperature the plant operates in as well as the heat transfer to the ambient environment.298,299 The Carnot efficiency represents the maximum performance limit, and cannot be achieved by real heat engines. A lower efficiency, called the Chambadal−Novikov efficiency, can be derived for a heat engine with irreversible heat-transfer processes operating at maximum power output.300 The Chambadal−Novikov efficiency ηCN is given by

ηCN = 1 −

TC TH

While current CSP plants use steam Rankine cycles, since they are efficient in the appropriate operating temperature range, work is being done to investigate new engines and working fluids that operate at higher temperatures, in preparation for when deployed collector/receiver configurations can operate efficiently at higher operating temperatures (and HTFs are developed that are stable at those temperatures). The exception for current plants using Rankine cycles is parabolic dish receivers as they are typically paired with Stirling engines, since the engine is mounted to the dish, which limits its size, and Stirling engines are more suitable at the kW scale. Stirling engines have been developed that could be paired with CSP systems that can achieve reasonable efficiencies (slightly below Chambadal−Novikov) for operating temperatures in the range of 400−800 °C.9,304 6.2.1. Supercritical Steam. Typical steam Rankine cycles are limited in operation temperature to about 600 °C. Higher efficiency can be achieved in supercritical steam Rankine cycles, using higher pressures and temperatures up to 760 °C.301 Supercritical fluids show compressibility and heat-transfer characteristics similar to those of liquids (reducing compressor work and enhancing regenerative heat exchange) but can still reach high temperatures, which typically lead to vaporization. Systems are limited to subcritical operating temperatures due to materials issues with the standard steels used for the boilers where the steam is heated. Reliable operation at higher temperatures will require different alloys, such as high nickel content steels.298,305 6.2.2. Supercritical CO2. A promising option for a heat engine operating at temperatures from 500 to 800 °C is supercritical CO2 used as the working fluid in a Brayton

(27)

The Chambadal−Novikov efficiency follows the same trend as the Carnot efficiency of increasing with operating temperature. The efficiency of real heat engines matches the Chambadal− Novikov efficiency much more closely than the Carnot efficiency, and as such the Chambadal−Novikov is generally a reasonable estimate to use for calculating heat engine AD

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Table 12. Typical Operating Temperatures and Efficiencies for Heat Engines Compatible with CSP cycle

operating temperature range (°C)

typical efficiency (%) (at max. temperature)

ref

steam−Rankine Stirling supercritical steam−Rankine supercritical CO2 Brayton combined cycle

350−600 400−800 600−760 500−800 >800

40 45 45 50 60

9 9 301 302 303

cycle.306 Supercritical CO2 (or s-CO2) engines have been considered for nuclear plants as well as CSP,231−233 although only small-scale generators have been demonstrated at this point.307 The primary advantages of the s-CO2 engine are high efficiency (potentially >50%) and small turbine size due to the relatively low fluid flow rate required.302 Advances in the design of sub-components and finding materials that are reliable and resistant to the corrosive nature of supercritical CO2 are needed before significant commercial adoption of s-CO2 engines will be possible.306,308 6.2.3. Combined Cycles. Another option for a heat engine to use with CSP is a combined cycle, which comprises a hightemperature “topping” cycle and a lower temperature “bottoming” cycle. Typically a Brayton cycle is used as the topping cycle and a Rankine cycle is used as the bottoming cycle. Combined cycles are very efficient heat engines, with the potential to surpass 60% heat to electricity conversion efficiency.303 Using a combined cycle is challenging for solar systems due to the high operating temperatures required (≥800 °C). As such, most efforts to use combined cycles with CSP consider integration with fossil-fuel fired plants,309,310 such as the 75-MW Martin Next Generation Solar Energy Center in Florida, even if the heat engine could be completely fueled by solar input in the design condition.311 If well-established cycles are used (e.g., air−Brayton for topping and steam−Rankine for bottoming), the challenges in further development of combined cycles with solar input largely lie in the receiver/concentrator end and efficient operation at high operating temperatures. There are, however, novel cycles that have been proposed for use as the bottoming cycles, such as organic Rankine cycles,312 mixed water−ammonia cycles,313 and organic flash cycles.314 These cycles offer the potential for higher efficiency with further development.

generator. Thermoelectric materials develop a voltage gradient when subjected to a temperature gradient due to the Seebeck effect, which arises due to majority carriers (electrons for n-type materials and holes for p-type materials) diffusing from the hot end to the cold end of the material.316 If the thermoelectric material is then put in series with an electrical load, a current will flow and electrical power is generated. TEGs are commonly associated with waste heat recovery applications;317 however, when coupled to a solar absorber, thermoelectrics can produce electricity from renewable solar energy. A schematic of a typical STEG configuration is shown in Figure 22.

Figure 22. Diagram of a solar thermoelectric generator (STEG). A temperature gradient arises when a pair of thermoelectric legs is sandwiched between an illuminated solar absorber (hot side) and a heat sink (cold side). The TE legs are electrically in series, which allows for current to flow if the TEG is connected to an electrical load.

STEG efficiency is the product of receiver efficiency (sunlight to heat efficiency) and TEG efficiency (heat to electricity efficiency). High-performance STEGs typically use spectrally selective absorbers, so improvement to receiver efficiency can be driven by the same techniques discussed in section 3. TEG efficiency is a function of the dimensionless thermoelectric figure of merit ZT, defined by

6.3. Direct Heat-to-Electricity Conversion

While deployed solar−thermal systems use traditional heat engines to convert heat to electricity via a two step process (heat to mechanical energy and mechanical energy to electricity), an active area of research is in developing direct heat-to-electricity conversion technologies that do not require an intermediate conversion to mechanical energy. An efficient and cost-effective direct conversion technology would allow for scalable solar−thermal systems (e.g., residential installations in addition to utility-scale), allowing investment in smaller plants that do not require the large amounts of capital necessary for >100-MW generators. Direct conversion technologies could also potentially offer better reliability and lower maintenance than current options due to the lack of moving parts in most direct heat-to-electricity technologies.315 The most active areas of research for direct heat-to-electricity conversion of solar energy are solar thermoelectric generators (STEGs) and solar thermophotovoltaics (STPV), both of which will be briefly reviewed below. 6.3.1. Solar Thermoelectric Generator (STEG). In a STEG, heat is converted to electricity using a thermoelectric

S2σ (28) k where S is the material Seebeck coefficient, σ is the electrical conductivity, and k is the thermal conductivity. This figure of merit is significant because the maximum efficiency achievable by a TEG with an average figure of merit ZT over its operating temperature range is given by318 ZT =

⎛ T ⎞⎛ 1 + ZT − 1 ⎞ ⎟ ηTEG = ⎜1 − C ⎟⎜⎜ TH ⎠⎝ 1 + ZT + TC/TH ⎟⎠ ⎝

(29)

where TC and TH are the TEG cold- and hot-side temperatures, respectively. The first bracketed term is Carnot efficiency, while the second term is a value less than one, which increases with increasing ZT. Thus, as ZT approaches infinity, the TEG efficiency approaches the Carnot limit. Early materials that achieved high ZT values (typically around 0.5−1) included AE

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bismuth telluride, lead telluride, and silicon germanium alloys.319 More recently, higher ZT values have been reported in these same materials in nanostructured forms,320−322 as well as new materials such as skutterudites and lead antimony silver tellurium.323−325 While the focus in thermoelectric materials development is often on increasing peak ZT, average ZT over the operational temperature range is more important for the performance of real devices, and should be the development driver for demonstrating high device efficiencies.326 In addition to the development of TE materials themselves, good contact materials with high thermal and electrical conductivity and Seebeck coefficients complementary to that of their TE material are also very important to demonstrating high performance in a device.327,328 There is significant room to improve ZT values and contact materials through investigating new materials systems and fabrication processes, and as such TEG efficiencies should continue to improve in the following decades. The first experimental demonstration of a STEG was reported by Telkes in 1954, for which an efficiency of 0.63% was achieved without concentration and 3.35% was achieved with concentration.329 Little experimental progress was made that outperformed this work until a demonstration of 4.6% solar to electric efficiency by Kraemer et al. in 2011, which was achieved under one sun insolation at an operating temperature around 200 °C.193 This is a rare example of a solar−thermal conversion process producing electricity without optical concentration, and was accomplished using an evacuated enclosure, a spectrally selective absorber, and thermal concentration (the absorber area is much larger than the cross-sectional area of the thermoelectric legs). Other simulation work has predicted that with optical concentration and higher temperature thermoelectric materials, STEGs surpassing 10% efficiency should be achievable for line-focus systems, and STEGs surpassing 15% efficiency should be achievable for point-focus systems.330−332 Most existing work on STEGs with concentration still use low operating temperatures (∼200 °C), thus achieving efficiencies similar to those obtained with the non-concentrated work.333 Recent work by Kraemer et al. has demonstrated 9.6% efficiency (not considering concentrator efficiency) at high concentration in a segmented STEG.334 If STEGs with comparable efficiencies to those of existing CSP technologies can be demonstrated, they could lead to more economic, scalable CSP systems. 6.3.2. Solar Thermophotovoltaics (STPV). In an STPV generator, heat is generated from the absorption of sunlight and is converted into thermal radiation. This thermal radiation is directed toward a single-junction thermophotovoltaic (TPV) cell where it is ultimately converted into electricity. The benefits of such a strategy are that the frequency dependent TPV converter is ideally illuminated by a photon spectrum that is much more efficiently converted than incident sunlight is on a PV converter. The challenge of STPV conversion is that an intermediate absorption/re-emission process is necessarily introduced into the system, and this must be done efficiently enough such that the spectral enhancement outweighs its effect. The main reason why the absorption/re-emission process has proven to be so inhibiting is due to the necessary high temperature of operation. Because STPV relies on the conversion of thermal radiation into electricity, even the lowest bandgap semiconductor materials (∼0.5 eV) require a blackbody spectrum of temperatures above 1000 °C in order to be efficient. While 1000 °C is certainly below the melting point of many materials, it is still an incredible engineering challenge to

Figure 23. Schematic of a STPV device. Incident concentrated solar radiation is thermalized at the hot absorber element. The heat conducts to a thermal emitter, which radiates photons to a PV cell. The photon spectrum is tailored either by spectrally selective emission or long-wavelength reflection.

put together a reliable system that is capable of efficient STPV conversion. The generation of heat from incident sunlight in an STPV converter has the same principles discussed in section 3. Once the absorber/re-emitter reaches its extraordinary equilibrium temperature, it will emit thermal radiation toward a singlejunction TPV cell. An important characteristic of this TPV generator is spectral control. There must be a systematic way of suppressing the illumination of the TPV cell by sub-bandgap photons. Historically, this has been accomplished on the “coldside” of the device, e.g., with a back surface reflector or an optical filter attached to the TPV cell. However, recent research has focused on the development of refractory materials that provide spectrally selective emission.75 A selective emitter is a material that, when heated to incandescence, is able to discriminate emission on the basis of the frequency of the photon. In this way, and because of Kirchhoff’s law of thermal radiation, a selective emitter is quite similar to a selective absorber. Instead of the transition from high to low emission separating the solar spectrum and the blackbody thermal emission spectrum, however, in a selective emitter the transition separates supra-bandgap photon emission from sub-bandgap photon emission. Chan et al. developed and integrated a one-dimensional photon crystal made of alternating thin films of Si/SiO2 in order to create both constructive and destructive wave interference.335 Rinnerbauer et al. developed two-dimensional photonic crystal by fabricating a large array of nanoscale cavities in a tantalum slab in order to take advantage of cavity modes for enhanced emission above the bandgap, with a tunable transition frequency.141 The emitter relies on the intrinsic low emission of the underlying metal at longer wavelengths. Li et al. used interesting optical properties of titanium nitride to develop high-temperature spectrally selective emitters.336 Arpin et al. developed a self-assembled three-dimensional photonic crystal using a tungsten-coated inverse opal structure.132 Recently, there have been a few successful demonstrations of solar-powered thermophotovoltaic converters. Datas et al. built a prototype that achieved about 1% solar to electric conversion efficiency. The low efficiency was largely due to overheating of the TPV cells and reliance on natural selectivity of hightemperature emitters.337 Lenert et al. integrated nanophotonic surfaces including vertically aligned carbon nanotubes to demonstrate a 3.2% STPV conversion efficiency.192 Rinnerbauer et al. used a monolithic two-dimensional photonic crystal AF

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absorber and emitter on a single chip to demonstrate 3.5% STPV conversion efficiency.80 Shimizu et al. also used a selective absorber/emitter to estimate up to 8% conversion efficiency, although this was not directly demonstrated.338 STPV efficiency is predicted to reach 20% for systems scaled up to larger absorber/emitter areas (which reduces the effect of edge losses) and that use higher quality PV cells and subbandgap filtering.192 A demonstration of an STPV device with efficiencies comparable to existing CSP plants would suggest the potential for economical STPV systems and smaller-scale CSP technology.

James joined the faculty at the University of Auckland as a Senior Lecturer. Dr. Bikram Bhatia is a Postdoctoral Research Associate at the Device Research Lab at MIT under Prof. Evelyn Wang. Bikram received his Ph.D. from the Department of Mechanical Science and Engineering at the University of Illinois at Urbana−Champaign (UIUC) in 2014. His doctoral research investigated waste heat harvesting using nanometerthick pyroelectric films. He received the B.Tech. degree in Mechanical Engineering from the Indian Institute of Technology Guwahati in 2008, and his M.S. from UIUC in 2010. He is currently working on solar−thermal energy conversion systems. David Bierman is a Ph.D. candidate in the Department of Mechanical Engineering at MIT, advised by Prof. Evelyn Wang. He received a B.S. in Mechanical Engineering from the University of Wisconsin− Madison in 2012, and an M.S. in Mechanical Engineering from MIT in 2014. His Ph.D. research is focused on solid-state solar−thermal energy conversion, including solar thermophotovoltaic converters and high-temperature material stability, as well as other fundamental problems in thermal radiation.

7. CONCLUDING REMARKS There is a wide spectrum of maturity for concentrating solar power (CSP) technologies, ranging from parabolic trough collector plants, which are a well-established commercial technology, to parabolic dish collectors, which have yet to be demonstrated at scales much greater than 1 MW. For the less mature technologies of power towers, linear Fresnel reflectors, and parabolic dishes, there are still many system level lessons to be learned as more of these systems become deployed. In addition to the plant-level challenges, there are compelling research questions that can be explored at each stage of a CSP plant: the concentrator, the receiver, the heat-transfer fluid, the thermal storage, and the heat engine all have room for improvement to push overall plant performance higher. With the added requirements of reliability and cost for actual deployment, challenges in increasing performance are made even greater. While daunting, the pragmatic challenges associated with use in commercial plants are still interesting from a technical perspective, as their solutions will involve innovative use of manufacturing methods and materials. With continued development moving into the future, CSP will maintain its role as an integral part of the renewable energy landscape.

Dr. Evelyn Wang is the Gail E. Kendall Associate Professor of Mechanical Engineering at MIT. She is the Associate Director of the Solid-State Solar-Thermal Energy Conversion (S3TEC) Center, an Energy Frontier Research Center funded by the U.S. Department of Energy. She received her B.S. in Mechanical Engineering at MIT in 2000, and her M.S. and Ph.D. from Stanford University in 2001 and 2006, respectively, each in Mechanical Engineering. She has received numerous awards including the DARPA Young Faculty Award in 2008, the AFOSR Young Investigator Award in 2011, and the ONR Young Investigator Award in 2012. Her research interests include micro/nano-scale heat and mass transport, two-phase transport, phasechange, nanoengineered surfaces, thermal management for highperformance systems, bioinspired micro/nano-systems, energy efficient systems, solar thermal energy conversion, and water desalination. Dr. Gang Chen is currently the Carl Richard Soderberg Professor of Power Engineering and Head of the Department of Mechanical Engineering at MIT. He obtained his Ph.D. degree from University of California, Berkeley, in 1993. He was a faculty member at Duke University (1993−1997) and University of California at Los Angeles (1997−2001) before joining MIT in 2001. He is a recipient of the NSF Young Investigator Award, the ASME Heat Transfer Memorial Award, the R&D100 Award, and the MIT McDonald Award for Excellence in Mentoring and Advising. He is a member of the U.S. National Academy of Engineering, a Guggenheim Fellow, an AAAS Fellow, an APS Fellow, and an ASME Fellow. He has published extensively in the area of nanoscale energy transport and conversion and nanoscale heat transfer. He is the Director of the Solid-State SolarThermal Energy Conversion (S3TEC) Center, funded by the U.S. DOE’s Energy Frontier Research Centers program.

AUTHOR INFORMATION Corresponding Author

*E-mail: [email protected]. Notes

The authors declare no competing financial interest. Biographies Lee Weinstein is a Ph.D. candidate in the Department of Mechanical Engineering at the Massachusetts Institute of Technology (MIT), advised by Prof. Gang Chen. He received a B.S. in Mechanical Engineering from the University of California, Berkeley, in 2011, and received an M.S. in Mechanical Engineering from MIT in 2013. His Ph.D. research has spanned multiple topics within CSP, including solar thermoelectric generators, directional selectivity, and transparent aerogels.

ACKNOWLEDGMENTS This work is supported in part by Advanced Research Projects Agency−Energy (ARPA-E) under Award No. DE-AR0000471 (for CSP power generation); as part of the Solid-State SolarThermal Energy Conversion Center, an Energy Frontier Research Center funded by the U.S. Department of Energy (DOE), Office of Science, Basic Energy Sciences, under Award No. DE-SC0001299/DE-FG02-09ER46577 (for basic research in spectral control and solid-state energy conversion); by U.S. DOE Office of Energy Efficiency & Renewable Energy, under Award No. DE-EE0005806 (for concentrated solar thermoelectric conversion devices); by ARPA-E under Award No. DE-

Dr. James Loomis received his Ph.D. in Mechanical Engineering from the University of Louisville (UofL) in 2013. His Ph.D. work focused on characterization and applications of photomechanical actuation in nanocarbon/elastomer composites. Additionally, while working in the UofL Micro/Nanotechnology Center, he developed software that enabled fabrication of complex 3D microstructures in photoresist. After receiving his Ph.D., James moved to Boston and joined the NanoEngineering Group at MIT as a Postdoc under Prof. Gang Chen. There he worked on continuous fabrication techniques for large-area polymer films with tunable thermal conductivity, and design of a utility-scale high-efficiency concentrating solar power receiver. In 2015, AG

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AR0000181 (for phase change material thermal energy storage); and by the Cooperative Agreement between the Masdar Institute of Science and Technology, Abu Dhabi, UAE, and the Massachusetts Institute of Technology, Cambridge, MA, USA (Reference 02/MI/MI/CP/11/07633/GEN/G/00 for low-concentration steam generation).

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DOI: 10.1021/acs.chemrev.5b00397 Chem. Rev. XXXX, XXX, XXX−XXX